Thermal and electrochemical process for metal production

Abstract

A method of winning a metal from its oxide ore by heating the ore in a partial vacuum or under an inert atmosphere in the presence of a reductant. The resulting product may be further reduced electrochemically to produce a purer metal.

Description

FIELD OF THE INVENTION

The present invention relates to the production of metals. The invention has particular utility in connection with the production of titanium and will be described in connection with such utility, although other utilities are contemplated, e.g., production of other high value multi-valence and high (2 or more) valance metals, in particular refractory metals such as chromium, hafnium, molybdenum, niobium, tantalum, tungsten, vanadium and zirconium which are given as exemplary.

BACKGROUND OF THE INVENTION

The properties of titanium have long been recognized as a light, strong, and corrosion resistant metal, which has lead to many different approaches over the past few decades to extract titanium from its ore. These methods were summarized by Henrie [1]. Despite the many methods investigated to produce titanium, the only methods currently utilized commercially are the Kroll and Hunter processes [2, 3]. These processes utilize titanium tetrachloride (TiCl₄) which is produced from the carbo-chlorination of a refined titanium dioxide (TiO₂) according to the reaction: TiO₂(s)+2Cl₂(g)+2C(s)→TiCl₄(g)+2CO(g). In the Kroll process [2] TiCl₄ is reduced with molten magnesium at ≈800° C. in an atmosphere of argon. This produces metallic titanium as a spongy mass according to the reaction: 2Mg(l)+TiCl₄(g)→Ti(s)+2MgCl₂(l) from which the excess Mg and MgCl₂ is removed by volatilization, under vacuum at 1000° C. The MgCl₂ is then separated and recycled electrolytically to produce Mg as the reductant to further reduce the TiCl₄. In the Hunter process [3,4] sodium is used as a reductant according to the reaction: 4Na(l)+TiCl₄(g)→Ti(s)+4NaCl(l) The titanium produced by either the Kroll or Hunter processes must not only be separated from the reductant halide by vacuum distillation and/or leaching in acidified solution to free the titanium sponge for further processing to useful titanium forms, but also require the recycling of the reductant by electrolysis. Because of these multiple steps the resultant titanium is quite expensive which limits its use to cost insensitive applications.

The high cost of the Kroll process results in a high cost of titanium products limiting their widespread utilization in spite of their exceptionally desirable properties. Since titanium's discovery, investigations have been conducted to produce titanium by more economical processing other than the metalothermic reduction such as magnesium or sodium reduction of TiCl₄, but without sufficient success to replace the high cost Kroll process. The intensive interest to develop low cost processing to produce titanium has recently spun several published processes. Since titanium primarily appears as the oxide (TiO₂), it can be conceived that an oxide feed to produce titanium could be more economical than making the chloride (TiCl₄) by carbo-chlorination of the oxide as the feed (TiCl₄) which is used in the Kroll process.

The US Bureau of Mines performed extensive additional investigations [1,5-8] to improve the Kroll and Hunter processes. Many other processes have been investigated that include plasma techniques [9-13], molten chloride salt electrolytic processes [14], molten fluoride methods [15], the Goldschmidt approach [16], and alkali metal-calcium techniques [17]. Other processes investigated have included aluminum, magnesium, carbothermic and carbo-nitrothermic reduction of TiO₂ and plasma reduction of TiCl₄[18] without measurable success. Direct reduction of TiO₂ or TiCl₄ using mechanochemical processing of ball milling with appropriate reductants of Mg or calcium hydride (CaH₂) also have been investigated [19] without measurable success. Kroll, who is considered as the father of the titanium industry [20] predicted that titanium will be made competitively by fusion electrolysis but to date, this has not been realized.

An electrolytic process has been reported [21] that utilizes TiO₂ as a cathode and carbon or graphite as the anode in a calcium chloride electrolyte operated at 900° C. By this process, calcium is deposited on the TiO₂ cathode, which reduces the TiO₂ to titanium and calcium oxide. However, this process is limited by diffusion of calcium into the TiO₂ cathode and the build-up of calcium oxide in the cell, which limits operating time to remove the calcium oxide or replacement of the electrolyte. Also the TiO₂ cathode is not fully reduced which leaves contamination of TiO₂ or reduced oxides such as TiO, mixed oxides such as calcium titanante as well as titanium carbide being formed on the surface of the cathode thus also contaminating the titanium.

In the Fray-Farthing-Chen (FFC) Cambridge process, or simply, the Fray process, titanium dioxide (TiO₂) is utilized as a cathode and electrolyzed with a graphite anode in molten calcium chloride (CaCl₂) which allegedly removes the oxygen from the TiO₂ in pellet form leaving titanium and with the graphite anode produces CO₂ at the anode. A fundamental teaching is that the oxygen ionized from the TiO₂ in the cathode must be dissolved in the electrolyte which is CaCl₂ for transport to the anode. In addition, it is stated that calcium titanites (Ca_xTi_yO_z) are formed as well as toxic chlorine is also given off initially at the anode. In technical public symposium, presenters of the FFC process have noted that the formation of calcium titanite is a problem to producing titanium metal and that the Columbic efficiency is very low at under 20% thus making the process expensive. Independent analysis, US Dept. of Energy Contract 4000013062 report, implies the cost of the FFC process is more expensive than the Kroll process and the product does not meet the purity of the standard Kroll material.

International patent publications WO 02/066711 A1, WO 02/083993 A1, WO 03/002785 A1 and U.S. Pat. No. 6,663,763 B2 also utilize TiO₂ as a cathode feed to electrolytically extract oxygen to produce titanium metal remaining at the cathode with oxygen discharged at the anode. Each of these publications state the Fray/FFC process produces titanium with residual oxygen, carbon and calcium titanite which is unsuitable for commercial use. International patent publication WO 02/066711 A1 to Strezov et al., assigned to BHP Steel, Ltd., reports that the Fray et al. process consist of ionizing oxygen at the titania (TiO₂) cathode under applied potential which oxygen removed or ionized from the TiO₂ cathode is dissolved in the CaCl₂ electrolyte and is transported to a graphite anode to be discharged as CO₂. The first aspect of the teachings of WO 02/066711 A1 is that the electrical contact to the TiO₂ cathode influences the reduction process and that a high resistive electrical conductor to the cathode is made part of the cathode. It is further reported the oxygen removed from the TiO₂ cathode in a pellet form passes onto solution and/or chemically reacts with the electrolyte cation. The teaching is that deposition of the cation at the cathode is prevented through controlled potential at under 3.0V in the CaCl₂ electrolyte. It is stated Al₂O₃ in the cathode with TiO₂ can also be reduced but non-uniformly with the only reduction taking place where the Al₂O₃ touches the cathode conductor. The publication WO 02/066711 A1 teaches the TiO₂ must be made into a pellet and presintered before use as a cathode and states the Fray et al. application mechanism is incorrect, produces 18 wt % carbon in the final titanium pellet as well as calcium titanites and silicates if silica is in the titania (TiO₂) pellets. This publication claims to avoid or prevent anode material (graphite/carbon) from transport into the cathode, but provides no teaching of how this is accomplished.

International publication WO 02/083993 A1 to Stresov et al. assigned to BlueScope Steel, Ltd., formerly BHP Steel, Ltd., teaches that the electrolyte to cathodically reduce pelletized TiO₂ must be calcium chloride containing CaO. This publication states that the CaCl₂ electrolyte is operated to produce Ca⁺⁺ cations which provide the driving force that facilitate extraction of O⁻⁻ anions produced by the electrolytic reduction of titania (TiO₂) at the cathode. It is reported that Ca metal exist in the electrolyte and that it is responsible for the chemical reduction of titania (TiO₂). It is also reported that significant amounts of carbon are transferred from the anode to the cathode thus contaminating the titanium and was responsible for low energy efficiency of the cell. This publication teaches replacing the carbon anode with a molten metal anode of silver or copper to eliminate carbon contamination of the reduced TiO₂. The teaching is that the cell potential be at least 1.5V but less than 3.0V with a cell potential above the decomposition potential of CaO. Again the titania (TiO₂) cathode is in the form of a solid such as a plate.

International publication WO 03/002785 A1 to Strezov, et al., also assigned to BHP Steel, Ltd., teaches the oxygen contained in the solid form of titantia (TiO₂) is ionized under electrolysis which dissolves in the CaCl₂ electrolyte. It is taught that the operating cell potential is above a potential at which cations are produced which chemically reduce the cathode metal oxide/TiO₂. It is further stated that chlorine (Cl₂) gas is removed at the anode at potentials well below the theoretical deposition, that Ca_xTi_yO_z is present at the TiO₂ cathode and that CaO is formed in the molten electrolyte bath which is CaCl₂ containing oxygen ions. It is also stated the potential of the cell must vary with the concentration of oxygen in the titanium requiring higher potentials at lower concentrations of oxygen to remove the lower concentrations of oxygen. It is unlikely to remove the oxygen from TiO₂ to low concentrations (i.e., 500 ppm) in a single stage operation. It is again taught that cations must be produced to chemically reduce the cathodic TiO₂ requiring refreshing the electrolyte and/or changing/increasing the cell potential. The method teaches carrying out the reduction of TiO₂ in a series of electrolytic cells of successively transferring the partially reduced titanium oxide to each of the cells in the series. The cell potential is above the potential at which Ca metal can be deposited via the decomposition of CaO wherein the Ca metal is dissolved in the electrolyte which migrates to the vicinity of the cathode TiO₂.

In U.S. Pat. No. 6,663,763 B2 which is substantially the same as international publication WO 02/066711 A1, it is taught that CaO must be electrolyzed to produce calcium metal and Ca⁺⁺ ions which reduce the titania (TiO₂) in the cathode with oxygen (O^═) migrating to the anode. This is very unlikely the mechanism. If Ca in metallic (Ca⁰) or ionic (Ca⁺) form reduces the TiO₂ the product of reduction will be CaO i.e., TiO₂+2Ca=Ti+2CaO. The produced calcium from electrolysis must diffuse into the titania (TiO₂) pellet to achieve chemical reduction as claimed and the formed CaO will then have to diffuse out of the Ti/TiO₂ which has been preformed and sintered into a pellet. If calcium metal (Ca⁰) or ions (Ca⁺⁺) are produced by electrolysis, the oxygen ions (O^═) produced from that electrolysis can diffuse to the anode. The calcium produced at the cathode and diffused into the bulk of the cathode thus chemically reducing the TiO₂, will form CaO which must become soluble in the electrolyte (CaCl₂) and diffuse out of the cathode before additional calcium can diffuse into the inner portion of the cathode for the chemical reduction.

It is also known from x-ray diffraction of the cathode that calcium titanite (CaTiO₃) forms as the TiO₂ is reduced. A possible reaction is O²⁻+Ca²⁺+TiO₂═CaTiO₃ which remains as a contaminate in the cathodically reduced TiO₂ to Ti.

U.S. Pat. No. 6,540,902 B1 to Redey teaches that a dissolved oxide in the electrolyte is required to cathodically reduce a metal oxide such as UO₂. The example is Li₂O in LiCl and the oxygen-ion species is dissolved in the electrolyte for transport to the anode which is shrouded with a MgO tube to prevent back diffusion of oxygen. It is reported the cathodic reduction of the oxide (examples UO₂ and Nb₂O₃) may not take place if the cathode is maintained at a less negative potential than that which lithium deposition will occur. The electrolyte (LiCl) should contain mobile oxide ions which may compress titanium oxide whose concentration of the dissolved oxide species are controlled during the process by controlled additions of soluble oxides. Which titanium oxide is not defined, however, as there are a plethora of different titanium oxides. It is generally known titanium oxides are not soluble in molten salts which accounts for the fact titanium is not electrowon from an oxide feed analogous to aluminum being electrowon from the solubility of Al₂O₃ in cryolite/sodium fluoride. While the Redey patent teaches cathodic reduction of UO₂ and Nb₂O₃ in a LiCl/Li₂O electrolyte, no residual oxygen concentrations are given in the cathode but it was estimated the reduction was 90% complete and no teaching is suggested TiO₂ would be reduced to very low oxygen levels.

International publication WO 03/046258 A2 to Cardarelli, assigned to Quebec Iron and Titanium Inc. (QIT) provides a review of electrolysis processes to produce titanium including Fray et al. This patent publication teaches a process analogous to Fray et al. except the process is carried out at a temperature above the melting point of titanium which is approximately 1670° C. A liquid slag containing titantia is used as a cathode on a cell bottom with an electrolyte such as CaF₂ floating on top and in contact with anodes such as graphite. Under electrolysis, the impure metals such as iron are deposited at the molten electrolyte titania slag interface and sink to the bottom of the slag since the iron is heavier. After the iron and/or other impurities are removed, titanium is reportedly deposited at the molten slag electrolyte interface and also sinks through the slag settling to the bottom of the cell for subsequent tapping. Oxygen ions diffuse through the electrolyte to an upper anode of graphite. It is suggested the overall reaction is TiO₂ (liquid)+C (solid)=Ti (liquid)↓+CO₂ (gas)↑.

No specific oxygen residual in the harvested titanium is provided.

Thus, current TiO₂ cathode electrolytic processes are no more commercially viable than the electrolytic processes before them.

It is known that metals can be won from their oxide ores by heating with a reductant which typically is carbon. Carbothermic reduction has been established as the most economical process to produce a metal in its pure metallic form. However, carbothermic reduction is not always possible to win a metal from its ore due to not sufficiently reducing impurities within the ore and/or not fully reducing the oxide which may lead to forming the carbide versus complete reduction of the metal oxide. Thus, oxides such as alumina (Al₂O₃) have not produced pure aluminum by carbothermic reduction. Similarly TiO₂ heretofore has not been carbothermically reduced to produce pure titanium. However, in our co-pending parent application, U.S. Ser. No. 10/828,641, filed Apr. 21, 2004, we describe how TiO₂ could be carbothermically reduced to TiO. Further investigations have shown it is possible to carbothermically remove more oxygen from the TiO to produce a suboxide of titanium, i.e., having a ratio of oxygen to titanium less than one. The more oxygen removed by the highly efficient and low cost carbothermic reduction, the less required to be removed by electrons in electrolytic reduction which frequently is quite inefficient. Thus the carbothermic reduction of TiO₂ as the first process step of producing titanium from TiO₂ is enabling.

Titanium is the fourth most abundant metal in the Earths' crust in several mineral forms. The most common utilized minerals are rutile (TiO₂) and ilmenite (FeTiO₃). Calcium titanates are also an abundant source which contains the element titanium. Utilized as mined or purified through various leaching and/or thermal processing's TiO₂ is the most utilized compound which has applications as pigment and for carbo chlorination to produce TiCl₄ which is reduced with metals such as magnesium (Kroll Process) or sodium (Hunter Process) that produces titanium metal or the chloride is oxidized to produce a highly purified pigment.

Titanium exists in multivalent species of Ti⁺⁴, Ti⁺³, and Ti⁺² in various anionic compositions such as the oxide or chloride. Except for the oxide those compounds are typically unstable in the ambient atmosphere. In general there has been limited application of these subvalent compounds which has not generated processing to produce the subvalent oxides or others compounds.

The high cost of titanium metal has limited its usage to critical aerospace where weight reduction over rides cost sensitivity. Because of the high cost of producing titanium by the Kroll or Hunter processes the cost volume ratio of titanium has tended to be inelastic. The holy grail of titanium is to reduce the cost of the primary metal as well as down stream processing cost. Initiatives are known to be underway to improve efficiency and reduce cost of the basic Kroll and Hunter processes as well as alternative processing involving electrolytic processing. It is known as stated above the FFC Cambridge process which cathodically reduces TiO₂ in a calcium chloride process is under development to reduce the cost of primary titanium. It is also known that calcium titanate also forms in this process which limits the process commercial viability. It is also known if cathodic reduction were conducted with a titanium suboxide such as TiO the calcium titanate problem would be eliminated as there is insufficient oxygen to straight forwardly form calcium titanate. It is also generally known that thermal reduction of metal oxides is more economical than using electrons produced by electrolysis which is why iron and many other metals are won by thermal reduction processes.

Since the initiation of the Kroll process to produce titanium in the mid twentieth century, it has been predicted titanium would be produced by an electrolytic process and that process would be similar to the Hall process to produce aluminum. The latter process consist of alumina (Al₂O₃) exhibiting solubility in fused cryolite (Na₃AlF₆) which is electrolyzed with a carbon anode that produces CO₂ with some CO and the metal aluminum. However, no equivalent process has been developed for solubalizing TiO₂. It is possible; however, that the suboxides of titanium can exhibit solubility in some fused salts that may include the alkali, alkaline earth and rare earth halides. However, no reliable low cost process has been available to produce the titanium suboxides that could be used as a feed to electrolytically produce titanium. The titanium suboxide could be utilized cathodically and electrolytically reduced to titanium metal without the calcium titanate problem when using TiO₂, and the titanium suboxide could be dissolved in fused salts with electrolysis with a carbon or inert anode to produce titanium. Either processing extreme can produce titanium more economically then the Kroll or Hunter processes. The enabling requirement to produce titanium by these electrolytic processes is a low cost source of titanium suboxides.

SUMMARY OF THE INVENTION

It is known that titanium suboxides as well as most metal suboxides can be produced by the metal reducing the highest valent oxide. For example silicon monoxide (SiO) can be produced by reducing SiO₂ with silicon (Si). That is SiO₂+Si+heat=2SiO. The SiO₂ can be reduced with other reductants but the product is contaminated with the reductant as well as unwanted other compounds can be produced. For example SiO₂+C+heat=SiO and SiC+CO. Producing a titanium suboxide by reducing TiO₂ with titanium metal is uneconomical since titanium metal must first be produced. Also if carbon is utilized as the reducing agent, titanium carbide is typically a contaminate. Titanium carbide has a very high free energy of formation which is exceeded only by zirconium and hafnium carbide. The free energy of formation of TiC is approximately 183 KJ/mole which makes it formation prominent in any carbon reduction process. As used herein the term “carbon” is meant to include carbon in any of its several crystalline forms including, for example, graphite. However, because of the economics of carbon and thermal reduction, the carbo-thermic reduction of TiO₂ would be ideal to produce titanium suboxides if the formation of TiC can be prevented and only one suboxide produced such as Ti₂O₃ or TiO.

BRIEF DESCRIPTION OF THE DRAWINGS

Further features and advantages of the present invention will be seen from the following detailed description, taken in conjunction with the accompanying drawings wherein:

FIGS. 1-3 show the XRD patterns of stoichiometric TiO₂—C heat treated in argon at 1300° C., 1400° C. and 1750° C. for one hour, respectively;

FIG. 4 shows thermodynamic equilibrium patterns thereof;

FIG. 5 shows the XRD patterns of stoichiometric TiO₂—C heat treated to 1450° C. in one step followed by heat treatment at 2100° C. in vacuum;

FIG. 6 shows the XRD patterns of 1:1:TiO₂—Ti heat treated to 1760° C. in vacuum;

FIG. 7 shows the XRD patterns of stoichiometric TiO₂—C heat treated to 1450° C. with a second heat treatment to 1800° C. in high vacuum;

FIG. 8 shows the XRD patterns of stoichiometric TiO₂—C from phenolic in a pre-mix heat to 1450° C. at one atmosphere pressure in argon;

FIG. 9 shows the XRD patterns of stoichiometric TiO₂—C from a 110° C. softening point coal tar pitch mixed at 190° C. and heat treated at 1650° C. at atmospheric pressure in argon;

FIG. 10 shows the XRD patterns of slag-C from a 110° C. softening point coal tar pitch mixed at 190° C. and heat treated at 1650° C. at atmospheric pressure in argon;

FIG. 11 shows the XRD patterns for Ilmenite ore treated with an intimate carbon coating on ore particles with heat treatment to 1650° C. in argon;

FIG. 12 shows the XRD patterns for Ilmenite ore treated with an intimate carbon coating on ore particles with heat treatment to 1650° C. in argon plus 1800° C. in a vacuum lower than 10⁻³ Torr;

FIG. 13 shows the XRD patterns of TiO₂ treated with an intimate mixture of carbon with heat treatment to 2100° C. at atmospheric pressure in argon; and

FIG. 14 shows the XRD patterns for Anatase TiO₂ with an intimate mixture of carbon with heat treatment to 2100° C. under argon at atmospheric pressure.

DETAILED DESCRIPTION OF THE INVENTION

To establish if a suboxide of titanium could be carbothermically produced several trials of mixing various carbon sources such as coke and carbon black, and heating to various temperatures at various pressures was performed.

Experimental Investigations to Carbothermically Reduce TiO₂

Stoichiometric amounts of TiO₂ powder and a source of carbon as finely ground coke or carbon black were mixed in a ball mill for periods up to 24 hours. The thoroughly mixed TiO₂ and carbon were then heat treated in a graphite element furnace purged with argon. The initial heat treatment was performed at 1300° C. for one hour. The heat treated mixed powder was subjected to x-ray diffraction (XRD) with the results showed in FIG. 1. As can be seen, the major product is TiC with a minor amount of Ti₃O₅. A sample of the TiO₂—C was heat treated to 1400° C. with the results shown in FIG. 2. A sample was heated to 1750° C. which also produced major amounts of TiC as shown in FIG. 3. The heating container was a graphite crucial which it was thought may be contributing carbon to the TiC formation.

Duplicate experiments were run in a magnesium oxide (MgO) crucible with the following results:

	Compound	Graphite Crucible	MgO Crucible
	TiC %	63	54
	TiO %	22	46
	Ti2O3 %	15	0

The small variation in compositions suggests the graphite crucible is not the major contribution to the formation of TiC.

Duplicate experiments were run but instead of atmospheric argon, a vacuum was generated with a fore pump to about 0.1 atmosphere. The TiC concentration was reduced to approximately 20%, with 30% TiO and 50% Ti₂O₃. The TiC composition was reduced with an increase in Ti₂O₃. The TiC is in a +4 valence state and unacceptable as a reduced valence state feed for electrolytic producing titanium. A thermodynamic equilibrium calculation was performed as shown in FIG. 4 which indicates that TiC is a major product component above about 1100° C.

A two step heat treatment was performed which consisted of first heating to 1450° C. and then in a second step heating to 2100° C. in vacuum of approximately 0.1 atmosphere. In this case only TiO was formed as shown in FIG. 5. Desirably TiO which is in a +2 valence is produced and serves as a feed to electrolytically produce titanium. However, heating to 2100° C. in vacuum is an expensive batch operation not conducive to commercial production of titanium at low cost, consequently less severe heat treatments were investigated to produce TiO.

First it was decided to define a base line using titanium metal to reduce TiO₂. Different ratios of TiO₂ to Ti were investigated. The best was a 1:1 ratio heat treated at 1760° C. also in vacuum which is shown in FIG. 6. As seen some higher oxides of Ti₃O₅ and Ti₂O₃ remained and pure TiO was not formed at these process conditions.

To avoid the high temperature treatment of 2100° C. to produce the TiO as shown in FIG. 5, the two stage treatment of first heating to 1450° C. to expel most of the CO followed by heating to 1800° C. in high vacuum was run. The result is shown in FIG. 7 which shows that TiO was indeed formed and some product desirably contained less oxygen than a 1:1 ratio to titanium. As desirable as this may be, the 1800° C. high vacuum treatment may be too costly to produce low cost titanium commercially. It is therefore desirable to develop less expensive processing to produce TiO.

The process given above was the through mixing of a carbon powder source and TiO₂ powder followed by the heat treatment steps discussed. A different approach to producing carbon and TiO₂ is to utilize a liquid which when pyrolized will provide a high yield of carbon. The TiO₂ particles can be uniformly mixed into the liquid precursor and then pyrolized. The precursor will produce a carbon film uniformly and intimately in contact with the individual TiO₂ particles. Example liquid precursors that have a high yield of carbon when pyrolized are furfural alcohol, resins such as phenyol formalide (phenolics) and pitches (coal and petroleum tars). Sugars and other materials can be used but their carbon char yield is low. Pitches have melting points from under 100° C. up to nearly 400° C. TiO₂ was mixed with phenolic resin such as Borden B1008 and heated to form a solid at approximately 110° C. TiO₂ was mixed with a 110° C. softening point coal tar pitch at a mixing temperature of 190° C. The char yield on the phenolic or coal tar pitch is approximately 50%. A stoichiometric mixture of each type of precursor was heated to temperatures of 1300° C. to 1650° C. with the results subjected to XRD analysis. The lower temperature, the 1450° C. example is shown in FIG. 8. As can be seen the major portion is TiO but some higher oxide of Ti₂O₃ remains; however, the amount of TiO produced is greater than when only particles of carbon and TiO₂ were heated together, and importantly no TiC was formed. The XRD of the sample heated to 1650° C. is shown in FIG. 9. At this temperature of 1650° C. heating at atmospheric pressure pure TiO is produced. The atmospheric pressure treatment is quite economical and the pure TiO produced can be used to electrolytically produce low cost titanium, e.g., by the electrochemical reduction method described in our aforementioned parent application.

The intimate mixing of the carbon precursor with the metal oxide can also be used to purify titania type ores. For example rutile ore, titania slag or ilmenite ore can be purified to a higher purity titanium oxide utilizing the intimate mixing of the carbon reductant. Titania slag which is a by product of pig iron production from ilmenite ore, obtained through QIT in Canada which has the composition shown in Table 1 was mixed with a 110° C. softening point coal tar pitch at 190° C. to obtain an intimate mixture of the carbon precursor and the slag particulate.

TABLE 1
Composition of TiO2 slag, a byproduct
of pig iron production from Ilmenite.
         Elemental composition in
Compound parts per million (ppm)
Al       2500
Ba       <100
Be       <100
Ca       <100
Cd       <100
Co       <100
Cr       <100
Cu       <100
Fe       7500
Hf       <100
K        <100
Mg       1500
Mn       <100
Mo       <100
Na       <100
Nb       <100
Ni       <100
P        <100
Pb       <100
Si       10,000
Sn       <100
Ta       <100
Ti       510,000
V        2000
W        2700
T        <100
Zn       <100
Zr       <100

The mixture was heated to 1650° C. in an argon inert atmosphere wherein the coal tar pitch was pyrolized with the heat treatment producing carbon in intimate contact with the titania slag particulate. The intimate carbon contact with the slag particulate produced TiO with the composition shown in Table 2.

TABLE 2
Composition of TiO2 slag from Ilmenite after the intimate mixture
with pitch and heating to 1650° C. in an inert atmosphere.
         Elemental composition in
Compound parts per million (ppm)
Al       5500
Ba       <100
Be       <100
Ca       <100
Cd       <100
Co       <100
Cr       <100
Cu       <100
Fe       1200
Hf       <100
K        <100
Mg       <100
Mn       <100
Mo       <100
Na       <100
Nb       <100
Ni       <100
P        <100
Pb       <100
Si       1800
Sn       <100
Ta       <100
Ti       745,000
V        2800
W        3200
T        <100
Zn       <100
Zr       <100

As can be seen in the carbothermic reduction, slag is purified from approximately 95% purity to 99+% purity utilizing the intimate carbon pretreatment before the heat treatment to 1650° C. The XRD after the 1650° C. treatment with the carbon in intimate contact with the TiO₂ slag is shown in FIG. 10.

Ilmenite which is iron titanite FeTiO₃ with a variety of impurities consists typically of the composition shown in Table 3.

TABLE 3
Composition of Ilmenite ore.
        ElementalComposition
Element Parts per million (ppm)
Al      4400
B       <100
Ba      <100
Be      <100
Ca      200
Cd      <100
Co      <100
Cr      500
Cu      <100
Fe      19.5%
HF      <100
K       <100
Li      <100
Mg      1400
Mn      9400
Mo      <100
Na      400
Nb      500
Ni      <100
P       800
Pb      <100
Si      1500
Sn      100
Ta      <100
Ti      38.5%
V       650
W       <100
Y       <100
Zn      200
Zr      <100

The ilmenite ore was mixed with 110° C. softening point coal tar pitch heated to 190° C. to provide intimate mixture of stoichiometric carbon and the ilmenite ore particles. The mixture was heated to 1650° C. heat treatment in an inert atmosphere which pyrolized the pitch providing intimate contact of the carbon on metal oxide particles. The chemical composition after the 1650° C. in an inert atmosphere which pyrolized the pitch providing intimate contact of the carbon on the metal oxide particles is shown in Table 4 and the XRD in FIG. 11.

TABLE 4
Composition of product after heating Ilmenite ore with
an intimate mixture of carbon to 1650° C.
        Elemental Composition
Element Parts per million (ppm)
Al      7100
B       <100
Ba      <100
Be      <100
Ca      <100
Cd      <100
Co      100
Cr      <100
Cu      <100
Fe      300
Hf      <100
K       <100
Li      <100
Mg      <100
Mn      <100
Mo      300
Na      <100
Nb      200
Ni      <100
P       <100
Pb      <100
Si      <100
Sn      100
Ta      <100
Ti      76.0%
V       <100
W       <100
Y       <100
Zn      <100
Zr      <100

Note the XRD pattern in FIG. 11 shows iron metal is present. The iron metal can be removed by leaching and/or complexing in an aqueous solution at ambient temperature. The iron and other impurities can be removed by heating in a vacuum less than 10⁻³ Torr to 1800° C. after or instead of the 1650° C. heat treatment. The purity of the high vacuum 1800° C. treated material is shown in Table 5 and the XRD in FIG. 12.

TABLE 5
Composition of product after heating Ilmenite ore with an intimate
mixture of carbon to 1650° C. with a second heat treatment
to 1800° C. in a vacuum less than 10−3 Torr.
         Composition
Elements Parts per million (ppm)
Al       6300
B        <100
Ba       <100
Be       <100
Ca       <100
Cd       <100
Co       <100
Cr       <100
Cu       <100
Fe       100
HF       <100
K        <100
Li       <100
Mg       <100
Mn       <100
Mo       300
Na       <100
Nb       200
Ni       <100
P        <100
Pb       <100
Si       <100
Sn       100
Ta       <100
Ti       85%
V        <100
W        <100
Y        <100
Zn       <100
Zr       <100

Examples of producing titanium metal with a starting feed of TiO₂ or impure ore are given in the following working examples:

EXAMPLE 1

Preparation

1. A TiO₂ pigment type feed obtained from the DuPont Company was mixed with powdered coal tar pitch (CTP) and a solvent of normal methyl pyrrolidone (NMP). The ratio was 80 parts TiO₂ and 30 parts of a 110° C. CTP and 80 parts of NMP. The NMP provides good fluidity of the mix and dissolves a portion of the CTP. After mixing by stirring, signal blade mixing, ball milling, attrition milling, etc. the mix is heated to evaporate the NMP for collection and reuse. The TiO₂ particulate is fully coated and intimately mixed with the pitch which chars or cokes to about 50% carbon with continued heating. The mixture was heated to 1700° C. under atmosphere pressure in a non-oxidizing atmosphere which is typically argon, CO₂, CO, etc. Nitrogen atmosphere is avoided to prevent the formation of titanium nitride. After the 1700° C. treatment the product was pure TiO with an XRD pattern analogous to that shown in FIG. 9. The produced TiO was utilized in four different trials to electrolytically produce titanium particulate. The trials were as follows:

• • Trial 1—The TiO was mixed with a 110° C. coal tar pitch which served as a binder and carbon black particulate to provide a stoichiometric mixture of TiO and carbon based on an off gas of 1:1 CO₂/CO. The mixture was pressed in a steel die at 190° C. to provide a solid on cooling. The composite anode was heated in an inert atmosphere to 1200° C. which pyrolized/carbonized the pitch binder. Resin or other precursors which yield carbon on heating in an inert atmosphere are satisfactory binders for producing a solid anode. The composite anode was utilized in a fused salt electrolyte consisting of the tri-eutectic of Li—K—Na chlorides. Virtually any fused salt mixture of the alkali and/or alkali halides are satisfactory as an electrolyte. A stainless cathode was used in a cell maintained in an inert atmosphere with electrolysis at 1 amp/cm² which produced titanium metal particulate in the size range of 10-500 microns.
  • Trial 2—The TiO was used as a cathode in a salt composition of 80% CaCl₂-20% LiCl operated at 850° C. The TiO was ground to minus 100 mesh (147 microns). The TiO particles were placed in a stainless steel mesh and placed in the salt electrolyte as a cathode with a graphite anode. A potential of 3.0V was applied between the graphite anode and TiO particles contained in the stainless mesh cathode. After 30 hours of electrolysis the cathodic particles were analyzed as titanium metal with a residual oxygen content of 2500 parts per million. During the electrolysis the anode gas was analyzed with a mass spectrometer to be primarily CO₂ with traces of CO.
  • Trial 3—The same electrolyte as in Trial 2 was utilized at the same temperature of 850° C. In this trial the TiO was ground to a minus 325 mesh (less than 44 microns). Two weight percent TiO was added to the electrolyte with stirring. After one hour stirring a stainless tube cathode was used with a 600 mesh stainless screen covering the bottom of the tube. A graphite rod was placed in the center of the stainless tube. Electrolysis was performed with the stainless tube as the cathode and the graphite rod as the anode. A cathode current density of 1 amp/cm² was utilized. After two hours electrolysis of the cathode anode assembly was removed from the salt electrolyte and water washed. Titanium metal particulate was produced in the size range of approximately 1 to 200 microns which demonstrates the TiO had solubility in the electrolyte in order to yield titanium metal on electrolysis.
  • Trials 4A and 4B—A closed cell inert atmosphere system was utilized that had tungsten coil resistors between two electrodes in the bottom of the reactor. Calcium fluoride (CAF₂) was used as the electrolyte and power applied to the tungsten resistors that brought the CaF₂ to a molten state and 1700° C. In Trial 4A, a TiO particle as given in Trial 2 was placed in a molybdenum screen and electrolyzed at 3.0V as a cathode with a graphite anode. Titanium was produced as a molten glob in the molybdenum screen. In Trial 4B, TiO-325 mesh was added to the CaF₂ electrolyte and electrolysis performed between a molybdenum cathode and a graphite anode. Molten droplets of titanium metal were produced at the molybdenum cathode which shows the TiO had solubility in the CaF₂ electrolyte at 1700° C. producing titanium metal in the molten state due to the electrolysis.

EXAMPLE 2

Preparation

Ilmenite ore obtained from QIT—Fer et Titane, Inc., of Quebec, Canada, which had the composition shown in Table 3 was mixed at room temperature with 110° C. softening point powdered coal tar pitch (CTP) in a ratio of 100 grams of ilmenite ore to 40 grams of CTP and 100 grams of toluene. The mixture was ball milled for four hours at room temperature to achieve good mixing and then heated to evaporate the toluene which was collected for reuse. The mixture was further heated to 1700° C. under an inert atmosphere at atmospheric pressure followed by reducing the pressure to 10⁻³ Torr or less and the temperature raised to 1800° C. and held for one hour. After cooling the treated ilmenite ore had the composition shown in Table 5. The purified TiO product was subjected to the same electrolysis trials listed in Trials 1, 2 and 5 producing purified titanium metal from an impure ore.

• • Trial 5—The same set-up was used as given in Trial 2. In this case hydrogen gas was bubbled over the TiO in the cathode. After electrolysis at 3V for 30 hours the titanium particles were subjected to vacuum evaporation of the residual salt at 1200° C. and 10⁻⁵ Torr vacuum. The residual oxygen content was 300 ppm.

It should be noted that since TiO is an electronic conductor with a conductivity superior to graphite, electrical contact is easily made which eliminates the necessity to form a partially sintered porous body to serve as a cathode for the electrolytic reduction to Ti metal particles. In the case of cathodic reduction of TiO₂ to the metal it is necessary to produce a porous perform in order that current can flow to the TiO₂ body whereas with the high electrolytic conduction of TiO particles are easily contacted to achieve cathodic reduction and making it possible for the continuous cathodic reduction as compared to batch processing of porous TiO₂ preforms.

The concentrations of titanium and oxygen in TiO are 74.96% titanium and 25.04% oxygen. This composition of TiO is typical of the material such as shown in FIG. 9. However, it is possible to further reduce the oxygen content to produce up to approximately 92% titanium. The higher titanium content is desirably obtained carbothermically which results in less electronic reduction in a second electrolysis step to obtain pure metallic titanium with very low oxygen contents of less than 500 ppm. Greater carbothermic reduction can be achieved by heating to higher temperatures than the 1650-1700° C. as above described.

Samples of TiO₂ (the ores of ilmenite, rutile, slag, etc can also be used), and carbon when intimately mixed and heated to higher temperatures, produces a higher titanium content in the remaining product. TiO₂ was intimately mixed at 190° C. with coal tar pitch in stoichiometric ratio to produce low oxygen content titanium and was heated to 2100° C. in a non-oxidizing atmosphere. The XRD of the product is shown in FIG. 13. The analysis of the product obtained from an outside laboratory, Wah Chang, showed a residual oxygen content of 5.4%. Residual carbon content is quite low in the range of 0.7 to 2%.

A sample was heated to 2800° C. in a non-oxidizing atmosphere in a graphite container. The XRD of that product showed primarily TiC which is believed the graphite crucible contributed to the TiC formation. A TiC crucible was fabricated and a TiO₂—C sample was heat treated to 2800° C. which resulted in little TiC and a reduced oxygen content of less than TiO in the residual titanium.

It is known that when TiO₂ and carbon are heated above about 1200° C. the product is a mixture of TiO and TiC. It is noted here that TiO₂ when heated at atmospheric pressure and/or at reduced pressure only TiO is produced as exemplified in the XRD patterns shown in FIGS. 10, 12 and 13 and verified from carbon and oxygen analysis which showed less than 1% carbon thus ruling out any appreciable amount of TiC formation with a remaining oxygen content depending on the heat treatment temperature of down to about 5% oxygen at 2100° C. It was also noted there was some difference in reactivity between the crystal forms of TiO₂ in rutile and anatase. The qualative results showed that anatase was more likely than rutile to produce a slight amount of TiC at 2100° C. than rutile as shown in the XRD pattern in FIG. 14. To produce TiO_x X≦1 at atmospheric pressure and/or vacuum an enabling step is the intimate mixing of the TiO₂/ore source with the carbon source as a pitch, resin or other carbon source in the liquid state.

The metal oxide produced by carbothermic reduction as above-described may then be formed into a feed electrode or used as a solute in the electrochemical reduction system described in our above parent application, Ser. No. 10/828,641.

The above embodiments and examples are given to illustrate the scope and spirit of the instant invention. These embodiments and examples are within the contemplation of the present invention. Therefore, the present invention should be limited only by the appended claims.

Claims

1. A method for winning a metal from its oxide ore, which comprises heating the ore under an inert atmosphere in the presence of a reductant.

2. The method of claim 1, wherein the reductant comprises carbon or graphite.

3. The method of claim 1, wherein the heating is conducted at a temperature in excess of 1100° C.

4. The method of claim 3, wherein the heating is conducted at a temperature of 1100-2100° C.

5. The method of claim 4, wherein the heating is at a temperature of 1400-1800° C.

6. The method of claim 1, wherein the carbon comprises a coal tar pitch.

7. The method of claim 1, wherein the carbon is derived from furfural alcohol.

8. The method of claim 1, wherein the carbon is derived from a resin.

9. The method of claim 8, wherein the resin comprises a phenolic resin.

10. The method of claim 1, wherein the heating is conducted in two steps.

11. The method of claim 1, wherein the ore comprises titanium oxide.

12. The method of claim 1, wherein said ore is heated under an inert atmosphere, under a partial vacuum, in the presence of a reductant.

13. A method for the production of a metal from its oxide ore, comprising the steps of: (a) heating the ore under an inert atmosphere in the presence of a reductant, whereby to produce lower oxide of said metal; and (b) subjecting the lower oxide of said metal produced in step (a) to an electrochemical reduction.

14. The method of claim 13, wherein the metal oxide from step (a) is mixed with carbon and formed into an anode for use in the electrochemical reduction of step (b).

15. The method of claim 13, wherein the ore comprises titanium oxide.

16. The method of claim 13, wherein the ore is heated in step (a) under an inert atmosphere, under a partial vacuum, in the presence of a reductant.

17. The method of claim 13, wherein the lower oxide of said metal produced in step (a) is employed as a solute in the electrochemical reduction in step (b).

18. The method of claim 13, wherein the lower oxide of said metal produced in step (a) is formed into an electrode and employed as a feed electrode in the electrochemical reduction in step (b).